Abstract

This papre describes a simple method of carbon disulphide determination in the air of working environment in the chemical companies and plants after its absorption into aprotic N,N-dimethylformamide solvent. Carbon disulphide absorbed into aprotic solvent was transformed by using ammonium hydroxide on sulphides which were determined by spectrophotometry. 5,5-Dithiobis(2-nitrobenzoic acid) and blue tetrazolium chloride were used as chromogenic sensing reagents. Colour-reducing products were measured at the wavelength of 500, respectively 520 nm. Detection limits for determination of carbon disulphide in the air are 0.2, respectively 0.4 mg·m−3.

1. Introduction

Carbon disulphide (CS2) is a strong neurotic poison with broad toxic influence on the human organism [1]. It belongs among important industrial chemical compounds. Enormous amount of CS2 is produced annually for synthetic fibres, rubber-making chemical compounds, or pesticides. CS2 is commonly present in oil industry. Significant part of CS2 is released into the working environment and contaminates it. Determination of CS2 in the working environment of chemical companies and plants is therefore one of the basic conditions for the health protection of workers and population.

Recently series of strongly powerful instrumental techniques have been applied in analytics using chromatographic separation methods [24]. Additionally traditional methods based on coloured reactions keep their relevancy. The oldest colorimetric and spectrophotometric methods are based on the reaction of CS2 with alcohols transformed on yellow copper xanthates [5]. Coloured dithiocarbamates have the most important relevance, which results from the reaction of CS2 with the prime and secondary amines and usually with ion of copper and nickel [69]. Other methods were described as well. One of the selection methods is based on the reaction of CS2, phloroglucinol, and nickel with production of the red salt of 2,4,6-trihydroxydithiobenzoic acid [10]. Reactions with thiols were used for spectrophotometry determination of CS2, for instance, benzyl thiol, which in the presence of potassium hydroxide reacts on yellow potassium benzyl-trithiocarbonate [11]. Spectrophotometric kinetic iodide-azide method was also used for the sensitive determination of carbon disulphide [12]. Indirect determination of CS2 with reagent of bis[4(4′-nitrophenyl)azo-2-nitrophenyl] disulphide is also known [13].

Determination methods of CS2 in the air are based mostly on its consumption of solid sorbent [14] or amine solutions, for instance, triethanolamine [15]. Based on previous experiments [16], a determination method of CS2 in the air was proposed and based on absorption of CS2 in aprotic solvent and its transformation to sulphides. Determination of sulphides was performed using 5,5-dithiobis(2-nitrobenzoic) acid or blue tetrazolium chloride, which are reduced to typical colouring products.

2. Experimental

2.1. Chemicals and Apparatuses

The following chemicals were used for experiments: carbon disulphide (Riedel-de Haën), 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB, Ellman’s reagent), blue tetrazolium chloride (BTC), that is, 3,3′-(3,3′-dimethoxy-4,4′-biphenylene)-bis(2,5-diphenyl-2H-tetrazolium chloride), N,N-dimethylformamide (DMFA), ammonium hydroxide 28%, and ethanol anhydrous (all from Sigma-Aldrich-Fluka). All chemicals were analytically pure. Water was distilled twice.

Two analytical reagents (A and B) were prepared.Analytical reagent A was prepared in the 100 mL volumetric flask by weighing 0.01 g of DTNB, then 0.2 mL ammonium hydroxide (28%) was added using pipette, and DMFA was added up to the mark.Analytical reagent B was prepared by solving 0.1 BTC in the mixture which contained 2 mL of ammonium hydroxide (28%) and 2 mL anhydrous ethanol and DMFA was added to the volume of 100 mL.Reagents must be fresh (8 hours). Under alkaline conditions, DTNB or BTC is already transformed into the colour product without any reactant.Measurements of absorbance were done on UV-VIS spectrophotometer Helios Alpha (Thermo Electron). The pump AirCheck 2000 (SKC) with flow meter was used for the air sampling.

2.2. Construction of Calibration Graph

Working solution was prepared by dissolving 0.1 mL CS2 in DMFA to a total volume of 100 mL. Cleanliness of CS2 was controlled by iodine-metric titration [17]. 4 mL of analytic reagent was measured off into a set of test tubes; using pipette 0 up to 100 μL base solution of CS2 was added and levelled with DMFA up to 20 mL. Absorbance values were measured against pure DMFA after 30 minutes of reaction time.

2.3. Determination of Carbon Disulphide in the Air

Steam-air mixture with CS2 prepared in testing chamber was absorbed into 15 mL of DMFA in the washing apparatus. Speed of air flow was 200 mL·min−1. After sampling, 4 mL of analytical reagent (A or B) was added to the absorbed substance and levelled with DMFA to 20 mL. Absorbance values were measured against pure DMFA after 30 minutes of reaction time.

Concentration of CS2 in the air (𝑐air) was calculated according the following formula: 𝑐air=𝑐abs𝑉abs𝑉air,(1) where 𝑐abs is the concentration of CS2 in the absorbed substance (μg·mL−1), 𝑉abs is the volume of absorbed substance (mL), and 𝑉air is the volume of air sample (L).

3. Results and Discussion

3.1. Reaction Mechanism

In the presence of ammonium hydroxide, CS2 reacts with ammonium dithiocarbamate, which with excess ammonium hydroxide is transformed into ammonium sulphide and ammonium thiocyanate. Sulphides reduced DTNB or BTC to coloured products suitable for spectrophotometric measurements. The course of chemical reaction for the case of DTNB reagent is displayed in Figure 1. Chemical structure of coloured product of reduction of BTC is presented in Figure 2. Value of 𝜆max 500 nm, respectively 520 nm, was read from the course of dependence of absorbance on wavelength (Figure 3). Aprotic solvent influences intensification of colouring of thiol (reaction product of sulphides with DTNB) from yellow (ethanol, 𝜆max=412nm) into red. Shift of 𝜆max was not observed with violet-coloured product during reaction with BTC.

3.2. Reaction Conditions

Ammonium hydroxide was used for transformation of CS2 to sulphides, but other compounds with ammonium ions (e.g., ammonium acetate) are suitable also. Reaction is progressing in the significant surplus of ammonium ions. Dependence of absorbance on concentration of ammonium ions, described as ratio of molar concentration of NH4+ and reagent (DTNB, BTC), is shown in Figure 4.

Transformation of CS2 to sulphides is progressing very quickly and with a good yield in aprotic solvents. This report describes application of DMFA, but it is also possible to use dimethyl sulfoxide (DMSO). Since DMSO solidifies at the temperature of 18°C, in the field and unfavourable climate conditions it is advantageous to use the mixture of DMFA/DMSO (1 : 1).

Stability of reaction balance is achieved for both methods within 30 minutes. The start of colouring is quicker with the DTNB method. One-half of the maximal absorbance at wavelength 𝜆max was achieved after 2 minutes and with the BTC method after 9 minutes.

One of the limiting factors of CS2 determination in the air is the effectiveness of its absorption in aprotic solvent. Effectiveness of absorption is mainly dependent on the speed of air flow during sampling. It is valid that the lower the speed of air flow, the higher the effectiveness of absorption. In practice the optimal time of the air sampling must also be taken into account, as not to exceed the acceptable limit. Air sampling with the speed of air flow 200 mL·min−1 for 50 minutes seems to be optimal. It corresponds with air sampling with the total volume of 10 L.

3.3. Analytical Characteristics

Basic parameters of determination of CS2 in the absorbed substance (molar absorptivity, detection limit, determination limit, Sandell’s sensitivity, and parameters of linear regression) are presented in Table 1. Sandell’s sensitivity was calculated for 𝐴=0.05. Detection limit was calculated from the formula 3𝜎/𝑏 and determination limit from the ratio 10𝜎/𝑏, where 𝜎 is a standard deviation of blind attempt and 𝑏 is the slope of calibration line.

Calibration line (Figure 5) was constructed on the basis of absorbance dependence on CS2 concentration in the air. Detection limit of CS2 in the air by the proposed procedure is 0.2, respectively 0.4 mg·m−3 (calculated according to the formula 𝑐air). In practice, with this procedure it is possible to determine CS2 (without dissolving the absorption solution) up to the concentration of 4.8 mg·m−3. It is fully acceptable for the requirements of hygienic control of the air in the working environment (e.g., in the Czech Republic PEL = 10 mg·m−3, NPK-P = 20 mg·m−3). Correctness of determination was verified by the method “inserted-found”, (see Table 2). Determination error is not higher than 20%.

3.4. Effect of Foreign Components

Reducing components present in the controlled air disturb determination of CS2 by the proposed method. Hydrogen sulphide reacts mostly with DTNB or BTC, which can originate for instance like a byproduct of synthesis of CS2 with methane and sulphur. To eliminate hydrogen sulphide, we can use filtration insert produced by impregnation of filtration paper or filtration materials from glass fibres by the solution of salts from certain heavy metals, for instance, lead, copper, or bismuth. This filtration insert is placed in the form of tube in front of the container with absorptive liquid. Sulphur dioxide (a result of pyrolysis of CS2) and volatile aliphatic triplets have significant disturbing influence. Overview of the selected the disturbing influences, which with DTNB and BTC produce the coloured reduction products, is in Table 3.

4. Conclusion

The proposed method allows spectrophotometric determination of CS2 in the workplace air of chemical companies and plants. This method is based on transfer of CS2 with the help of ammonium ions to sulphides, which react further with DTNB or BTC to the characteristically coloured reaction products. Reactions are in progress in the medium of aprotic solvent, with advantage in DMFA. The method is simple and easy to instrumentation and technique. The sensitivity method, detection limits, and the range of use are comparable with other spectrophotometric methods described in the literature [9, 14, 15].

The advantage of the proposed analytical process (based on transfer of CS2 to sulphides) is in the opening of new development possibilities of colorimetric and spectrophotometric methods for CS2 determination. Interconnection of CS2 and sulphides analysis allows using and modifying a relatively significant number of standard methods for determination of sulphides (hydrogen sulphide) with regard to concrete conditions and determined objectives.

Acknowledgment

This work was prepared as part of a research project supported by the Ministry of Interior of the Czech Republic (Project VG20102013048).